Investigating the effect of copper sulfide precursors and the effect of the ratio of copper sulfide to iron oxide on the photocatalytic activity of CuS/Fe3O4 magnetic composites for aniline removal under visible light radiation
Subject Areas :parvaneh nakhostin panahi 1 , faeze peyrovi 2 , mohammad hossein rasuli fard 3
1 - Department of Chemistry, Faculty of Science, University of Zanjan, Zanjan, Iran
2 - Department of Chemistry, Faculty of Science, University of Zanjan, Zanjan, Iran
3 - Department of Chemistry, Faculty of Science, University of Zanjan, Zanjan, Iran
Keywords: Photocatalyst, Aniline, Fe3O4, CuS,
Abstract :
Aniline is one of the simplest aromatic amine compounds, which is highly toxic. The aniline inhalation causes inflammation of the lungs and in high concentrations, eating or inhaling its vapor is fatal. The aim of the present study is to remove aniline by photocatalytic process with copper sulfide under visible light radiation. First, the effect of the type of copper and sulfur precursors in the synthesis of copper sulfide was investigated. Next, in order to create magnetic property in the photocatalyst and to easily separate it from the suspension by magnet, composites with different ratios of copper sulfide and magnetic Fe3O4 were prepared. The X-ray diffraction, scanning electron microscope and ultraviolet-visible emission reflection spectroscopy were used to survey the physical and chemical properties of the synthesized samples. The results revealed that copper sulfide synthesized with copper acetate and thioacetamide shows the highest photocatalytic activity compared to copper sulfides synthesized with other precursors. Also, by adding Fe3O4 to copper sulfide, in addition to creating magnetic property, the performance of photocatalysis and the percentage of aniline removal also increases.
[1] Downing, R.S.; Kunkeler, P.J.; Van Bekkum, H.; Catalysis Today 37, 121-36, 1997.
[2] Delnavaz, M.; Ayati, B.; Ganjidoust, H.; Iranian Journal of Health and Environment 2, 76-87, 2009.
[3] Wang, G.C.; Wang, P.C.; Sci. Technol. Rev. 32, 72-8, 2014.
[4] Urata, M; Uchida, E; Nojiri, H; Omori, T; Obo, R; Miyaura, N; Ouchiyama, N.; Bioscience, Biotechnology, and Biochemistry 68, 2457-65, 2004.
[5] Firoze, M.K.; Kaphalia, B.S.; Boor, P.J.; Ansari, G.A.; Archives of Environmental Contamination and Toxicology 24, 368-74, 1993.
[6] Tang, W.Z.; An, H.; Chemosphere 31, 4157-70, 1995.
[7] Ayodhya, D.; Veerabhadram, G.; Materials Today Energy 9, 83-113, 2018.
[8] Nezar, S.; Cherifi, Y.; Barras, A.; Addad, A.; Dogheche, E.; Saoula, N.; Laoufi, N.A.; Roussel, P.; Szunerits, S.; Boukherroub, R.; Arabian Journal of Chemistry 12, 215-224, 2019.
[9] Borah, D.; Saikia, P.; Sarmah, P.; Gogoi, D.; Rout, J.; NathGhosh, N.; Bhattacharjee, C.R.; Inorganic Chemistry Communications 142, 109608, 2022.
[10] Wang, Y; Liu, Q.; Wong, N.H; Sunarso, J.; Huang, J.; Dai, G.; Hou, X.; Li, X.; Ceramics International 48(2), 2459-2469, 2022.
[11] Szczepanik, B.; Słomkiewicz, P.; Applied Clay Science 124, 31-38, 2016.
[12] Ashouri, R.; Rasekh, B.; Kasaeian, A.; Sheikhpour, M.; Yazdian, F.; Dehghani Mobarakeh, M.; Journal of Molecular Modeling 27(3), 1-14, 2021.
[13] Gao, L.; Wang, E.; Lian, S.; Kang, Z.; Lan, Y.; Wu, D.; Solid State Communications 130, 309-12, 2004.
[14] Loekitowati Hariani, P.; Faizal, M.; Ridwan, R.; Marsi, M.; Setiabudidaya, D.; International Journal of Environmental Science and Development 4, 336-40, 2013.
[15] Wu, Z.C.; Li, W.P.; Luo, C.H.; Su, C.H.; Yeh, C.S.; Advanced Functional Materials 25, 6527-37, 2015.
[16] Mihaylov, B.V.; Hendrix, J.L.; Nelson, J.H.; Journal of Photochemistry and Photobiology A: Chemistry 72, 173-7, 1993.
[17] Cheng, H.; Huang, B.; Lu, J.; Wang, Z.; Xu, B.; Qin, X.; Zhang, X.; Dai, Y.; Physical Chemistry Chemical Physics 12, 15468-75, 2010.
[18] Zhang, Y.; Tang, Z.R.; Fu, X.; Xu, Y.J.; Applied Catalysis B: Environmental 106, 445-52, 2011.
[19] Ding, S.; Han, M.; Dai, Y.; Yang, S.; Mao, D.; He, H.; Sun, C.; ChemCatChem 11(15), 3490-3504, 2019.
_||_[1] Downing, R.S.; Kunkeler, P.J.; Van Bekkum, H.; Catalysis Today 37, 121-36, 1997.
[2] Delnavaz, M.; Ayati, B.; Ganjidoust, H.; Iranian Journal of Health and Environment 2, 76-87, 2009.
[3] Wang, G.C.; Wang, P.C.; Sci. Technol. Rev. 32, 72-8, 2014.
[4] Urata, M; Uchida, E; Nojiri, H; Omori, T; Obo, R; Miyaura, N; Ouchiyama, N.; Bioscience, Biotechnology, and Biochemistry 68, 2457-65, 2004.
[5] Firoze, M.K.; Kaphalia, B.S.; Boor, P.J.; Ansari, G.A.; Archives of Environmental Contamination and Toxicology 24, 368-74, 1993.
[6] Tang, W.Z.; An, H.; Chemosphere 31, 4157-70, 1995.
[7] Ayodhya, D.; Veerabhadram, G.; Materials Today Energy 9, 83-113, 2018.
[8] Nezar, S.; Cherifi, Y.; Barras, A.; Addad, A.; Dogheche, E.; Saoula, N.; Laoufi, N.A.; Roussel, P.; Szunerits, S.; Boukherroub, R.; Arabian Journal of Chemistry 12, 215-224, 2019.
[9] Borah, D.; Saikia, P.; Sarmah, P.; Gogoi, D.; Rout, J.; NathGhosh, N.; Bhattacharjee, C.R.; Inorganic Chemistry Communications 142, 109608, 2022.
[10] Wang, Y; Liu, Q.; Wong, N.H; Sunarso, J.; Huang, J.; Dai, G.; Hou, X.; Li, X.; Ceramics International 48(2), 2459-2469, 2022.
[11] Szczepanik, B.; Słomkiewicz, P.; Applied Clay Science 124, 31-38, 2016.
[12] Ashouri, R.; Rasekh, B.; Kasaeian, A.; Sheikhpour, M.; Yazdian, F.; Dehghani Mobarakeh, M.; Journal of Molecular Modeling 27(3), 1-14, 2021.
[13] Gao, L.; Wang, E.; Lian, S.; Kang, Z.; Lan, Y.; Wu, D.; Solid State Communications 130, 309-12, 2004.
[14] Loekitowati Hariani, P.; Faizal, M.; Ridwan, R.; Marsi, M.; Setiabudidaya, D.; International Journal of Environmental Science and Development 4, 336-40, 2013.
[15] Wu, Z.C.; Li, W.P.; Luo, C.H.; Su, C.H.; Yeh, C.S.; Advanced Functional Materials 25, 6527-37, 2015.
[16] Mihaylov, B.V.; Hendrix, J.L.; Nelson, J.H.; Journal of Photochemistry and Photobiology A: Chemistry 72, 173-7, 1993.
[17] Cheng, H.; Huang, B.; Lu, J.; Wang, Z.; Xu, B.; Qin, X.; Zhang, X.; Dai, Y.; Physical Chemistry Chemical Physics 12, 15468-75, 2010.
[18] Zhang, Y.; Tang, Z.R.; Fu, X.; Xu, Y.J.; Applied Catalysis B: Environmental 106, 445-52, 2011.
[19] Ding, S.; Han, M.; Dai, Y.; Yang, S.; Mao, D.; He, H.; Sun, C.; ChemCatChem 11(15), 3490-3504, 2019.
